Mechanism Analysis of Strengthening the Coral Reef Sand Foundation by Dynamic Compaction Method Based on Discrete Element Theory

WANG Jianping; AN Shao; FANG Bin

doi:10.3724/j.gyjzG23102513

Volume 54 Issue 10

Oct. 2024

Turn off MathJax

Article Contents

Article Navigation > INDUSTRIAL CONSTRUCTION > 2024 > 54(10): 199-204

WANG Jianping, AN Shao, FANG Bin. Mechanism Analysis of Strengthening the Coral Reef Sand Foundation by Dynamic Compaction Method Based on Discrete Element Theory[J]. INDUSTRIAL CONSTRUCTION, 2024, 54(10): 199-204. doi: 10.3724/j.gyjzG23102513

Citation:

WANG Jianping, AN Shao, FANG Bin. Mechanism Analysis of Strengthening the Coral Reef Sand Foundation by Dynamic Compaction Method Based on Discrete Element Theory[J]. INDUSTRIAL CONSTRUCTION, 2024, 54(10): 199-204. doi: 10.3724/j.gyjzG23102513

Citation:

PDF( 20876 KB)

Mechanism Analysis of Strengthening the Coral Reef Sand Foundation by Dynamic Compaction Method Based on Discrete Element Theory

doi: 10.3724/j.gyjzG23102513

Naval Research Institute, Beijing 100071, China

Received Date: 2023-10-25
Available Online: 2024-11-06

Abstract

Abstract

The dynamic compaction method for reinforcing foundation has the advantages of significant effectiveness, saving in materials and short construction period, which is suitable for reinforcing coral reef sand foundation. To conduct the mechanism of strengthening coral reef sand foundation by dynamic compaction method, a numerical model was established based on discrete element method which could simulate both the shape of coral reef sand and the characteristics of soil porosity changes during the dynamic compaction process. The numerical model reliability was verified by field test results, and finally the coral reef sand particle crushing process, force chain development and foundation settlement under different tamping energy were analyzed, so as to clarify the internal mechanism of foundation reinforcement.The research results showed that the foundation settlement of adopted discrete numerical model showed a good alignment with that of field results, proving that the model had low error and high reliability; under the action of dynamic compaction method, the pores of coral reef particles decreased, the particle fragmentation zone gradually developed to both ends of the ramming pit, and the force chain was concentrated and radially distributed towards the center of the ramming pit; the greater the tamping energy, the greater the surface and foundation settlement within a certain depth range, and the particle fragmentation zone and force chain developed in both depth and breadth.
- discrete element,
- dynamic compaction method,
- coral reef sand,
- foundation reinforcement,
- mechanism analysis

FullText(HTML)

References(17)

References

[1]	沈扬,冯照雁,邓珏,等. 南海珊瑚砂地基承载力模型试究[J].岩土力学,2021,42(5):1281-1290.
[2]	吴杨,崔杰,李能,等. 岛礁吹填珊瑚砂力学行为与颗粒破碎特性试验研究[J].岩土力学,2020,41(10):3181-3191.
[3]	汪稔,吴文娟. 珊瑚礁岩土工程地质的探索与研究:从事珊瑚礁研究30年[J].工程地质学报,2019,27(1):202-207.
[4]	王刚,叶沁果,查京京.珊瑚礁砂砾料力学行为与颗粒破碎的试验研究[J].岩土工程学报,2018,40(5): 802-810.
[5]	沈扬,沈雪,俞演名,等.粒组含量对钙质砂压缩变形特性影响的宏细观研究[J].岩土力学,2019,40 (10): 3733-3740.
[6]	邓华,邱明喜,殷立静. 吹填珊瑚砂地基软弱夹层特性[J].水运工程,2019(11):156-159.
[7]	王伟光,郝秀文,李婉,等. 碾压方式对珊瑚砂地基工程特性的影响[J].长江科学院院报,2020,37(8):113-119.
[8]	夏玉云,乔建伟,刘争宏,等. 振动碾压对吹填珊瑚砂地基工程特性影响的试验研究[J].地基处理,2020,31(4):277-284.
[9]	王笃礼,肖国华,李兴,等. 基于振动碾压下沉量对比的一种珊瑚砂次压缩系数推测方法[J].岩土工程技术,2019,33(2):75-78.
[10]	李铭,韦港荣,蒋恒. 东南亚珊瑚砂岛礁类地基处理方法研究[J].西部交通科技,2019(6):42-44,158.
[11]	秦志光,袁晓铭,曹振中,等. 吹填珊瑚礁砂地基处理方法适用性与加固效果应用研究[J].自然灾害学报,2021,30(1):78-88.
[12]	罗尚奕,张浩天,高康华,等. 冲击荷载下珊瑚砂单颗粒动态破碎模拟研究[J].土工基础,2021,35(6):754-757.
[13]	CABBOU B.Behavior of granular materials[M]. Berlin:Springer, 2014.
[14]	马宗源,徐清清,党发宁. 碎石土地基动力夯实的颗粒流离散元数值分析[J].工程力学,2013,30(增刊1):184-190.
[15]	贾敏才,王磊,周健. 干砂强夯动力特性的细观颗粒流分析[J].岩土力学,2009,30(4):871-878.
[16]	XU M, HONG J, SONG E. DEM study on the effect of particle breakage on the macro-and micro-behavior of rockfill sheared along different stress paths[J].Computers and Geotechnics, 2017, 89:113-127.
[17]	王建平,郭东,张宏波,等. 珊瑚碎屑地基加固方法现场对比试验[J].工业建筑,2016,46(5):119-123.